Prediction of the Service Life of Metal-Polymer Gears Made of Glass and Carbon Fibre-Reinforced Polyamide, Considering the Impact of Height Correction

Chernets, Myron; Kornienko, Anatolii

doi:10.12913/22998624/124553

Artykuł - szczegóły

Tytuł artykułu

Prediction of the Service Life of Metal-Polymer Gears Made of Glass and Carbon Fibre-Reinforced Polyamide, Considering the Impact of Height Correction

Autorzy

Chernets Myron , Kornienko Anatolii

Treść / Zawartość

Pełne teksty:

Pobierz

Identyfikatory

DOI

10.12913/22998624/124553

Warianty tytułu

Języki publikacji

Abstrakty

Calculation methods for predicting the service life of metal-polymer gears with height correction are proposed. Two methods for gear service life estimation are presented: a simplified method that assumes constant tooth interaction conditions and an improved method that takes into account wear-induced changes in tooth interaction conditions. Spur cylindrical gears with a steel gear and a pinion made of polyamide composite reinforced with carbon and glass fibres are studied. The effect of height correction on the service life of the gears is examined, considering the type of tooth engagement. It is established that with the improved method the service life of the gear is by up to 1.3 times longer than that calculated by the simplified method at optimal height correction coefficients. Optimal service life of the gear is achieved when the correction coefficients are x1 = – x2 = 0.1. The effect of the coefficient of friction on gear service life is investigated. It is found that the service life of the gear with a carbon fibre-reinforced pinion is by 8.1...9.3 times longer than that of the gear with a glass fibre-reinforced pinion.

Słowa kluczowe

calculation methods metal-polymer cylindrical gear polyamide composites height correction gear durability

metody obliczeniowe cylindryczna przekładnia metalowo-polimerowa kompozyty poliamidowe korekta wysokości trwałość przekładni

Wydawca

Lublin University of Technology
Polish Society of Ecological Engineering (PTIE), Branch of PTIE in Lublin

Czasopismo

Advances in Science and Technology. Research Journal

Rocznik

2020

Tom

Vol. 14, no 3

Strony

15--21

Opis fizyczny

Bibliogr. 25 poz., fig.

Twórcy

autor

Chernets Myron

m.czerniec@pollub.pl

Department of Сomputerization and Robotization of Production, Lublin University of Technology, Nadbystrzycka st. 36, 20-816 Lublin

autor

Kornienko Anatolii

Department of MachineScience, National Aviation University, Lubomyr Huzar prosp. 1, 03680 Kiev, Ukraine

Bibliografia

1. Brauer J., Andersson S. Simulation of wear in gears with flank interference – a mixed FE and analytical approach. Wear, 254, 2003, 1216–1232.
2. Cathelin J., Letzelter E., Guingand M., De Vaujany J.P., Chazeau L. Experimental and Numerical Study a Loaded Cylindrical PA66 Gear. Journal of Mechanical Design, 135, 2013, 89–98.
3. Chernets M.V., Kelbinski J., Jarema R.Ja. Generalized method for the evaluation of cylindrical involute gears. Materials Science, 1, 2011, 45–51.
4. Chernets M.V., Yarema R.Ya., Chernets Ju.M. A method for the evaluation of the influence of correction and wear of the teeth of a cylindrical gear on its durability and strength. Part 1. Service live and wear. Materials Science, 3, 2012, 289–300.
5. Chernets M.V., Chernets Ju. M. Evaluation of the strength, wear, and durability of a corrected cylindrical involute gearing, with due regard for the engagement conditions. Journal of Friction and Wear, 37 (1), 2016, 71–77.
6. Chernets M.V., Chernets Yu.M. A technique for calculating tribotechnical characteristics of tractive cylindrical gear of VL – 10 locomotive. Journal of Friction and Wear, 37 (6), 2017, 566–572.
7. Chernets M., Chernets Ju. The simulation of influence of engagement conditions and technological teeth correction on contact strength, wear and durability of cylindrical spur gear of electric locomotive. Proc. JMechE. Part J: Journal of Engineering Tribology, 231 (1), 2017, 57–62.
8. Chernets M.V., Shil’ko S.V., Pashechko M.I., and Barshch M. Wear resistance of glass- and carbonfilled polyamide composites for metal-polymer gears. Journal of Friction and Wear, 39 (5), 2018, 361–364.
9. Chernets M. Method of calculation of tribotechnical characteristics of the metal-polymer gear, reinforced with glass fiber, taking into account the correction of tooth // Eksploatacja i Niezawodnosc – Maintenance and Reliability, 21 (4), 2019, 546–552.
10. Flodin A., Andersson S. Wear simulation of spur gears. Tribotest J., 3(5), 1999, 225–250.
11. Flodin A., Andersson S. A simplified model for wear prediction in helical gears. Wear, 249 (3–4), 2001, 285–292.
12. Hooke C.J., Kukureka S.N. Liao P., Rao M., Chen Y.K. The Friction and Wear of Polymers in NonConformal Contacts. Wear, 200, 1996, 83–94.
13. Grib V. Solution of tribotechnical tasks with numerous methods. Science, Moscow, 1982.
14. Kahraman A., Bajpai P., Anderson N.Е. Influence of tooth profile deviations on helical gear wear. J. Mech. Des., 127 ( 4), 2005, 656–663.
15. Kalacska G., et al. Friction and Wear of Engineering Polymer Gears. Proceedings of WTC2005 World Tribology Congress III, Sept. 12–16, 2005, Washington.
16. Keresztes R., Kalacska G. Friction of Polymer/ Steel Gear Pairs. Plastics and Rubber, 45, 2008, 236–242.
17. Kindrachuk M.V., Volchenko A.I., Volchenko D.A., Zhuravlev D.Y., Chufus V.M. Electrodynamics of the Thermal Contact Friction Interaction in Metal-Polymer Friction Couples. Material Science, 54 (1), 2018, 69–77.
18. Kolivand M., Kahraman A. An ease-off based method for loaded tooth contact analysis of hypoid gears having local and global surface deviations. J. Mech. Des.,132 (7), 2010, 0710041–0710048.
19. Pasta A., Mariotti Virzi G. Finite element method analysis of a spur gear with a corrected profile. J. Strain Analysis, 42, 2007, 281–292.
20. Rymuza Z. Predicting wear in miniature steel – polymer journal bearings. Wear, 137 (2), 1990, 211–249.
21. Rymuza Z. Tribology of polymers. Archives of civil Mechanical Engineering, 7 (4), 2007, 177–184.
22. Shil’ko S.V., Starzhinskii V.E. Prediction of Wear Resistance of Gearing with Wheels Made of Reinforced Composites. Journal of Friction and Wear,14 (3), 1993, 7–13.
23. Shil’ko S.V., Starzhinsky V.E., Petrokovets E.M., Chernous D.A. Two-Level Calculation Method for Tribojoints Made of Disperse-Reinforced Composites: Part 1. Journal of Friction and Wear, 34 (1), 2013, 65–69.
24. Sukumaran J., et al. Modelling Gear Contact with Twin-Disc Setup. Tribology International, 49, 2012, 1–7.
25. Wielieba W. Bezobsługowe łożyska ślizgowe z polimerów termoplastycznych. Wyd. Politechniki Wrocławskiej, Wrocław, 2013.

Uwagi

Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2020).

Typ dokumentu

Bibliografia

Identyfikator YADDA

bwmeta1.element.baztech-ace3c607-890c-48ea-826f-f2743a3babd1